DE1797294C3 - Multiple photographing device with a lenticular lens plate - Google Patents

Description

The invention relates to a multiple photographing device with a first object-side lens part, a diaphragm which has an opening which is significantly smaller than the cross section of the first objective part, which when changing from one subject to another in a standard level to the optical Axis of the lens is displaceable and is arranged in the vicinity of or within the first lens part, and a second objective part, designed as a lenticular lens plate, which consists of a plurality of microlenses exists, is arranged in the beam path behind the first objective part and on one in the image plane of the Second lens part arranged photosensitive material a plurality of partial images of the first Objective part can generate thrown through the opening of the overall image.

Such a multiple photographing device is made of Pop. Photography, vol. 60, 1967, issue 1st p.! 12ff. known. Such a multiple photographing device can, for. B. for ordinary photography, but also for copying purposes be used; It is possible to record a plurality of Take pictures, these being encrypted by splitting the pictures into a plurality of partial pictures and therefore not easily recognizable for everyone. A preferred registration area is in Microdocumentation, with the encryption effect di <* again playing an essential role here.

As shown in FIG. 1 shows the mode of operation of such a device shown, it has this as the first object-side objective part /. U. a relatively large first lens I, a second lens line 2 and a diaphragm directly behind the lens. The / wide lens part 2 consists of a multitude of microlenses, which / u are combined in a l.insenrasu'rplaitc and are arranged, il.it! They form a grid consisting of rows and columns of microlenses. The second objective part is used to break down the inverted image generated by the first objective part into a large number of small partial images. The second objective part generates real, non-inverted partial images of the inverted BHdes generated by the first objective part on a light- or radiation-sensitive material 4 (for the sake of simplicity, only light-sensitive material will be referred to below). The opening

ίο 3 is arranged and designed so that it can be moved vertically and horizontally in a plane extending essentially normal to the optical axis O of the lens. The opening 3 ensures that each of the microlenses, which together form the second objective part 2, throws only one of infinitesimal partial images of the image generated by the first objective part onto a specific part of the photosensitive material 4.

The same effect can also be achieved if the opening 3 or, more precisely, the Opening 3 bearing rushing end is located directly from or within the first Objeklivtcils 1. Further can the photosensitive material, which is arranged behind the second lens part 2, also on the rear surface of this second lens part be attached if this rear surface is at the same time the image plane of the second lens. Another possibility is that the photosensitive material 4 in a suitable Distance from the second lens part 2 is maintained.

If an inverted image A of an object is now generated by the first objective part between the first objective part 1 and the second objective part 2, the part Aa of the image A which lies in the beam path between the opening 3 and a first microlens element 2a of the second objective part 2 becomes , projected onto the light-sensitive material 4 as a non-inverted real image Aaa. In a similar way, the light rays representing another part An of the image A fall through the opening 3 onto a different microlens element 2n of the second objective part 2, which then generates the corresponding partial image Ana on the light-sensitive material.

If now the opening 3 z. B. moved to the position indicated at 3 <i and the lens is directed at another object, an image B of this other object is generated. A part Ba of the image B, which lies in the light path between the opening 3a and the microlens element 2a of the second objective part 2, is then projected onto the photosensitive material 4 by the microlens element 2a in the form of a non-inverted real image. In a similar way, another part Bn of the image S, which lies in the light path between the opening 3a and another microlens element 2n, is projected by the latter onto the photosensitive material 4 as a non-inverted real image.

To deepen the discussion of the mode of operation of a multiple photographing device, the relationships in the case of a single microlens of the microlens plate 22 can be considered. If the Diaphragm 23 is in a certain position, then a small sub-area of the image capture area exposed behind the observed microlens of the microlens plate 22 with this partial image. Will the location of the

fs aperture 2 ^ changed to a different position, one becomes one. ¹ other small sub-area of the image capture area hinit.T di-r microlens of microlens plate 22 exposed. I> n_-s!) - (ifiiiot. That it is possible. Not each other

overlapping areas of the image capture area behind the viewed the microlens of the microlens plate 22 to expose imagewise when the diaphragm 23 assumes different positions from one another.

In such a photographing device, the s Number of pictures to be taken by the ratio of the total exposure area.: Jch distance of the the aperture plate having the opening determines the area of the opening. The number of images that are on a single piece of light-sensitive material can be recorded, so by the Ratio of the effective exposure area of the first lens in iier plane of the opening to the area of the Opening hestimmi. If one assumes that the effective diameter of the first objective part in the plane of the opening is 30 mm, so that its focal length 95 mm is the distance between the opening and the image generated by the first lens part is 80 mm, that the distance between the image and the second objective is 40 mm that the opening;. ' χ 2 mm and that the dimension of the The displacement of the opening both in the vertical and in the horizontal direction amounts to J mm in each case, see above 49 pictures can be photographed by opening the opening 7 steps in both directions is moved.

How many st> li. : · ■ - ■ Partial areas on the catchment area behind the observed microlens never 1 overlapping can be exposed, is thus determined by the ratio of the largest possible aperture of the ray enjo gangs in the plane of the diaphragm plate to the area Aperture determined. In other words, the total number of pictures to be taken becomes thereby determines how often the aperture can be adjusted to different positions without them moving Superimpose positions on each other.

Since each microlens only images a partial image of the entire image to be imaged, and also only one Subfield of the image capture area assigned to it is required, a plurality of images can actually be used one and the same recording medium are recorded.

Those generated by the multiple photographing device Images of the objects are in the form of a single piece of photosensitive material finely divided sub-images, so that it is impossible to tell which old objects are on the photosensitive material are included.

The recorded images can be reproduced with an optical image reproduction system, which is similar to the optical system of the multiple photographing apparatus by using the Direction of the beam path reverses.

In such multiple photography devices, the first lens, which the R Richturg des Light path determined as a function of the position of the opening, are made so large that they covers the entire egg area in which the opening can be moved in the vertical and horizontal directions. If you train this lens in such a good quality, 6ο That the image errors, in particular the image field curvature, are sufficiently corrected, so the multiple photography Votrichtung relatively large and heavy: the technical effort is also high.

Of the lulling is an object to provide a Vielfachfotografier device according to the preamble of claim 1 i \>, which requires only a relatively simple lens, and the field curvature is corrected by an additional simple optical means.

This object is achieved in that a relatively simple lens or Linsenkumbination is not sufficiently corrected Bildf M- provided krümrnung first objective part and in that the focal lengths of the second objective part forming Mikroünsen with the distance from the optical axis of the lens are changed such that this compensates for the curvature of the lens field.

According to the invention, the focal lengths of the microlenses of the second lens are different around one another held in such a way that the curvature of the image field of the first lens at least approximates is balanced. For example, the focal lengths of the microlenses are close to the circumference of the second lens part belinden, different from those of the microlenses, which are in the Miitelbereich of the second lens part. The distance from the center of the curved field of view to the crolenses. which are in the center of the / large part of the lens, is less than the / wipe the outer edge areas of the image field of the first lens part and the in the outer rim areas of the second lens part arranged microlenses. Therefore, the focal lengths of the microlenses have to widen in the Zeiiiralieil of / Objectively also be lower than those of the Microscope in the outer rim of the second Objective part, if you want to get that from that The curved image produced by the first lens part is reproduced sharply on the flat photosensitive material will. That is, the focal lengths of the microlenses should preferably be with their distance from the center the / wide lens increase. However, it is not necessary in practice that the focal lengths of all the second lens part bullenden microlenses under are different. That is, the the / wide objective oil forming microlenses can be divided into a certain number of groups from the center / around the circumference of the / wide lens part, the focal lengths of the microlenses of each group among each other the same, but different from the focal lengths of the neighboring groups.

When the curved image produced by the first lens part through a / wide lens part of the above is corrected and thrown onto the photosensitive material, a relatively simply constructed first lens part can be used.

In the following, with reference to FIG. 2 of the drawing shows a preferred embodiment of the invention described.

In the embodiment shown in FIG a lens 21 of relatively simple construction is provided as the first objective part. Yours is one Orifice plate with an opening 23 is assigned. The lens 21 forming the first objective part generates an image I, that is arched. Finally, a lenticular lens plate 22 is provided as a second lens part, which consists of a There is a group of microlenses, each of which is sufficiently smaller than the lens 21.

The partial images of the image I generated by the microlenses ('er lenticular plate 22 are taken from the Microsensives thrown onto a photosensitive material 24, which is attached to the rear surface of the Lenticular plate is arranged.

If one now looks at the bundles of rays (and (.1, which come from the opening 21 and to the microniniM · 27.1

fall on the periphery of the lenticular lens plate 22 and the microlens 22aa in the central area of the lenticular lens plate 22, it can be seen that the distances a and aa between the infinitesimal images I .; and \ aa of the bundles of rays i and Ca and the corresponding microlenses 22; i and 22; yes are different from one another. This difference depends on the curvature of the image plane of image I. The distance a is greater than the absland aa. Since each of the microlenses that make up the lenticular lens 22 produce a real image of a portion of the image I, the focal length of each of the microlenses must be determined to best suit the distance between the microlens and the corresponding infinitcsimal part of the image I. suitable. In this way it can be achieved that the lines of infinity of the image I are sharply imaged on the photosensitive material 24, which is at the same distance from all the microlenses 24.

In view of this, the focal length of the microlens 22, -; determined so that it corresponds best to the Bikkibstand, / of the microlens 22, i, while the focal length of the microlens 22.7a is determined so that it best reflects the image distance aa of the microlens 22; /. In this way, the focal lengths of all microlens elements are determined so that they correspond as closely as possible to the associated image distance. In this way, each infinitesimal part of the image I is sharply imaged on the light-sensitive material 24 with the aid of the corresponding microlens.

1 sheet of drawings

Claims (1)

Claim: Multiple photographing device with a first object-side objective part, a diaphragm, which is a Has opening that is much smaller than that Cross-section of the first lens part, which when changing from a subject to a further is displaceable in a standard plane to the optical axis of the lens and in the vicinity or is arranged within the first lens part. and one designed as an inner grid plate second lens part, which consists of a large number of Microlenses is arranged in the beam path behind your first lens part and on an in the image plane of the second lens part arranged photosensitive material a plurality of Can generate partial images of the overall image projected through the opening by the first objective part, characterized in that a relatively simple lens or as the first objective part (21) Lens combination is provided with insufficiently corrected curvature of field and that the Focal lengths of the second objective part (22) forming microlenses with the distance from the optical axis of the lens are changed in such a way that this causes the field curvature of the lens is balanced.